Performance optimization study on a novel waste heat flow-based wick-finned distillation system for clean and sustainable pure water production

IF 7.1 2区 工程技术 Q1 ENERGY & FUELS Sustainable Energy Technologies and Assessments Pub Date : 2024-11-12 DOI:10.1016/j.seta.2024.104076
Rohtash Goswami , Ranjan Das , Sayantan Ganguly
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Abstract

In this work, a novel wick and copper-finned distillation system has been developed based on the flow of waste heat from a biomass engine to efficiently produce a large amount of pure water to meet sustainable development goals. In this novel design, six copper-made fins are employed at a specific location on the waste heat pipe to boost the evaporation process, and a double-layer wick is employed over the glass to enhance the condensation process, which collectively leads to improved system performance. The performance optimization of the distillation system has been investigated to obtain the maximum mass of distilled water by varying the operating conditions of the input factors. Further, the Box-Behnken Design, Analysis of Variance, and Regression methods are applied to develop the empirical correlations between the input factors and a response parameter. The effects of various input factors on the response parameter are studied by response surface analysis through surface and contour plots. The experimental results revealed that the maximum value of the mass of the distilled water is obtained as 2.407 kg during 100 min of run at 321 °C of waste heat inlet temperature, 45° of glass angle, and 0.08 m of basin water height. Employing wick and copper fins in the distillation system has positively affected the yield of distilled water productionand increases the output from 2.054 kg to 2.407 kg with a 17.18 % improvement at the optimal conditions. It has been suggested that the highest waste heat inlet temperature level needs to be preferred to produce a large amount of distilled water. In contrast, the moderate levels of glass angle and basin water height provide the maximum output. The quadratic correlation is found to be in good agreement with the experimental values, with a maximum error of 12.03 %. The production cost of distilled water from the present system is found to be 1.91 INR/kg (0.023 USD/kg) through economic analysis.

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基于余热流的新型鳍状灯芯蒸馏系统性能优化研究,用于生产清洁和可持续的纯净水
在这项工作中,基于生物质发动机的废热流,开发了一种新型灯芯和铜鳍蒸馏系统,以高效生产大量纯水,实现可持续发展目标。在这种新颖的设计中,在废热管的特定位置使用了六片铜制鳍片,以促进蒸发过程,并在玻璃上使用了双层灯芯,以加强冷凝过程,从而共同提高了系统性能。对蒸馏系统的性能优化进行了研究,以通过改变输入因素的操作条件获得最大质量的蒸馏水。此外,还采用了方框-贝肯设计法、方差分析法和回归法来建立输入因素与响应参数之间的经验相关性。通过曲面图和等值线图,采用响应曲面分析法研究了各种输入因素对响应参数的影响。实验结果表明,在余热入口温度为 321 °C、玻璃角为 45°、盆水高度为 0.08 m 的条件下,蒸馏水的质量在 100 分钟的运行过程中达到最大值 2.407 kg。在蒸馏系统中使用灯芯和铜翅片对蒸馏水产量产生了积极影响,在最佳条件下,产量从 2.054 千克增加到 2.407 千克,提高了 17.18%。研究表明,要生产出大量蒸馏水,必须选择最高的废热入口温度。相反,适中的玻璃角度和盆水高度可提供最大产量。二次相关性与实验值吻合,最大误差为 12.03%。通过经济分析发现,本系统的蒸馏水生产成本为 1.91 印度卢比/公斤(0.023 美元/公斤)。
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来源期刊
Sustainable Energy Technologies and Assessments
Sustainable Energy Technologies and Assessments Energy-Renewable Energy, Sustainability and the Environment
CiteScore
12.70
自引率
12.50%
发文量
1091
期刊介绍: Encouraging a transition to a sustainable energy future is imperative for our world. Technologies that enable this shift in various sectors like transportation, heating, and power systems are of utmost importance. Sustainable Energy Technologies and Assessments welcomes papers focusing on a range of aspects and levels of technological advancements in energy generation and utilization. The aim is to reduce the negative environmental impact associated with energy production and consumption, spanning from laboratory experiments to real-world applications in the commercial sector.
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